The PPCS In-Vessel Component Concepts (focused on Breeding Blankets)

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1 International School of Fusion reactor Technology Erice, July 26 August 1, 2004 The PPCS In-Vessel Component Concepts (focused on Breeding Blankets) Presented by L. Giancarli Commissariat à l Energie Atomique, CEA/Saclay, France Acknowledgements: The work presented in this talk has been performed by the CEA and the FZK Design Teams within the framework of the EU Power Plant Conceptual Studies and of the EU DEMO Blanket Studies. Most of the presented pictures are derived from viewgraphs made by the two Teams.

2 The PPCS In-Vessel Components Concepts Plan of the Presentation 1. Introduction on In-Vessel Components 2. Breeding Blankets 1. Functions and Strategy 2. Present Choices for EU PPCS and DEMO 3. Design & Analyses Details of the EU PPCS Blankets 4. Blanket Systems and Integration Issues (examples) 5. R&D Issues (medium term, long term) 3. Divertors (short overview) 1. Functions and Strategy 2. Choices for EU PPCS 4. Conclusions

In-Vessel Components Location & Conditions blanket manifolds TF coils upper ports The most severe working conditions and requirements shield 8 9 7 10 6 11 5 4 3 2 1 divertor plates b c a e d h f g

3 In-Vessel Components Location & Conditions blanket manifolds TF coils upper ports The most severe working conditions and requirements shield divertor plates b c a e d h f g central ports vacuum vessel lower ports blanket modules High surface heat flux 0.5 (FW) 5 MW/m 2 (div.) High neutron wall loading (FW) ~2.5 MW/m 2, ~150 dpa(fe) Operation under void (plasma) low coolant leakages High magnetic field (~7 Tesla) (high MHD effects) Moreover : Remote access in high radiation field (maintenance, inspection, repairs, diagnistics, )

Reactor breeding blankets Three crucial functions for a Power Plant Convert the neutron energy (80% of the fusion energy) in heat and collect it by mean of an high grade coolant to reach high

4 Reactor breeding blankets Three crucial functions for a Power Plant Convert the neutron energy (80% of the fusion energy) in heat and collect it by mean of an high grade coolant to reach high conversion efficiency (>30%) in-pile heat exchanger Produce and recover all Tritium required as fuel for D-T reactors Tritium breeding self-sufficiency Contribute to neutron and gamma shield for the superconductive coils resistance to neutron damages

5 Reactor breeding blankets Tritium breeding self-sufficiency : a necessity Main Tritium production reaction : 6 Li + n => T + 4 He + 4,8 MeV Typical T-production rate in dedicated fission reactor : 1-2 kg T / GW th / y Typical T burn rate in a fusion reactor : ~50 kg T / GW th / y (~150 gt/gw th /day) Need to produce all T and collect it on-line (because of initial inventory and safety) Tritium Breeding Ratio, TBR = T prod /T burn > 1 (at least) Tritium breeding self-sufficiency : a severe constraint D + T 4 He + n 60-80% 4 He + T 6 Li + n 20 to 40 % of neutrons are not available for T-production Neutron Losses n-leakage through ports, divertor region, gaps % n-parasitic absorptions on other materials (structures) % blanket n-leakage (<5%) Neutronics requirements minimize n-losses small gaps and openings, minimization of structures and coolant fractions add a n-multiplier Pb or Be (n,2n) or Li 7 (n, n T)

6 Breeding blankets materials Main available breeders (Li-based compounds) Liquid Lithium (7.5% 6 Li) Eutectic Pb-17Li (T m 235 C) Molten Salts : FLiBe, FLiNaBe Li-Ceramics : Li 4 SiO 4, Li 2 TiO 3, LiO 2 Neutron multipliers Be (n, 2n) Pb (n, 2n) 7 Li (n, n T) Main Structural Materials Ferritic/Martensitic Steels Vanadium Alloys Composites SiC/SiC Main Coolants for Nuclear (relevant T for good efficiency)) Pressurized Water (PWR) Helium Liquid Metals : Li (Na), Pb-17Li A breeding blanket has to be designed using a combination of these materials. Best concepts are an optimum compromise between all constraints which has to take into account: temperature, pressure, loads levels compatibility between materials under the defined working conditions safety low activation/low radwaste characteristics performances (e.g., TBR) technology availability and manufacturing processes as a function of timescale reliability & others..

7 Breeding Blankets Development Timescale Reactors JET, TFTR, JT60, Tore Supra Asdex, etc. ITER (1) international DEMO (1 or more?) 1st Commercial Power Plant (1 or more?) 10th of the kind PPCS Main Plasma Physics (control,stability, impurities, shutdown proc., heating, etc.) Plasma Ignition Long D-T Pulses Systems Integration Tritium Breeding Self-sufficiency High Safety Standards Electricity Production at Competitive Cost High Electricity Production at Competitive Cost Possible Advanced Goals Magnetic Field Advanced Systems (e.g., super cond. coils) Test of DEMO Blanket Mock-ups (Test Module) Electricity Production (high efficiency, but low reliability system) Reliability Low Level Waste Reliable Technology Low Level Waste Operation Years ~ ~ ~ From ~2050 > 2080

8 Breeding Blankets Concepts Power Plant Model Basic Parameters A B AB C D Major Radius (m) Aspect Ratio Plasma Current (MA) Toroidal Field on axis (t) TF on TF Coil Conductor (T) Elongation (95% and separatrix) 1.7/ / / / /2.1 Triangularity (95% and separatrix) 0.27/ / / / /0.7 Q Engineering Parameters Fixed Electrical Output (GW) Fusion Power (GW) P add (MW) Avg. Neutron Wall Load FW (MW/m 2 ) Surface Heat Flux on FW (MW/m 2 ) Max. Divertor Heat Load (MW/m 2 ) Selected Breeding Blanket Type WCLL HCPB HCLL DCLL SCLL

9 PPCS Breeding Blankets Concepts Short Term Concepts (for models A, B, AB) A -Water-Cooled Lithium-Lead (WCLL) coolant T in /T out 285/325 C, 15.5 MPa B -Helium-Cooled Pebble-Bed (HCPB) ceramic/be blanket, coolant T in /T out 300/500 C, 8 MPa AB -Helium-Cooled Lithium-Lead (HCLL) coolant T in /T out 300/500 C, 8 MPa To be tested in ITER (B & AB) Can be used for DEMO (after selection) Use of martensitic/ferritic steel structures (low activation EUROFER) R&D still required, results expected on time for DEMO time schedule To demonstrate feasibility of Fusion for DEMO To demonstrate performance objectives for Fusion Medium Term Concept (model C) C -Dual-Coolant Lithium-Lead (DCLL) & He He T in /T out 300/480 C, 8 MPa LiPb T in /T out 480/700 C Need SiC/SiC insulators + high Temp. HX Can be used in DEMO at later stage? Use of martensitic/ferritic steel structures (low activation EUROFER) Significant R&D required, relatively long time is required Long Term Concept (model D) D Self-Cooled Lithium-Lead (SCLL) LiPb T in /T out 700/1100 C Use of SiC/SiC structures Need very large & lengthy R&D (50 y?) Very good efficiency & safety standard Attractive but high development risk

10 Blanket Concept A : Water-Cooled LiPb Module inlet Module outlet

11 Blanket Concept A : Water-Cooled LiPb Used Calculation Models For 3D MCNP Montecarlo Neutronics Analyses y Double Walled Tube First Wall Tube x Stiffener Back plate For 2D CASTEM Thermo-mechanical Analyses Lithium-lead

12 Blanket Concept A : Water-Cooled LiPb Main Analyses Results Mechanics: the modules box resists to 15.5 MPa in accidental conditions (RCC-MR) Thermo-mechanic: acceptable T (< 550 C in FW steel, < 480 C on Pb-17Li interface), acceptable stresses and deformation (RCC-MR) Neutronics: 3-D TBR = 1.06 at 90 at% 6 Li enrichment, 30 dpa/y in FW steel, 850 appm H/y, 300 appm He/y Steam Generator Tritium: maximize confinement and extraction (LiPb at ~2 mm/s to avoid MHD pressure drops) High Pressure Turbine Blanket cooling loop Blanket Coolant External Circuits Reheater Moisture separator High Pressure Heaters Low Pressure Turbine Divertor Preheater Feedwater Tank Divertor cooling loop

13 Blanket Concept B : Helium-Cooled Ceramic/Be He-cooled stiffening grid Modular Concept for HCPB/HCLL blankets He-collectors back-plates Breeder Unit He-cooled FW & Box

14 Blanket Concept B : Helium-Cooled Ceramic/Be Stiffening Grid (details) HCPB Breeder Unit

15 Blanket Concept B : Helium-Cooled Ceramic/Be Scheme of the Heflow path in each module Scheme of a possible module attachment to the back shield

Tritium Breeding Ratio: 1.12 Neutron multiplication: 1.

16 Blanket Concept B : Helium-Cooled Ceramic/Be 3D Montecarlo Neutronics Analyses (MCNP) Breeder : Li 4 SiO 4 ( 6 Li 30%) Blanket thickness (inb/outb): 41/51 cm Tritium Breeding Ratio: 1.12 Neutron multiplication: 1.78 Deposited Nuclear Power - whole blanket: 3000 MW - Vacuum Vessel & Shield: 310 MW Energy multiplication: 1.38

Breeder Unit Front He in/out unit manifolds He unit

17 Blanket Concept AB : He-Cooled Lithium-Lead Modular Concept for HCPB/HCLL blankets : details of the HCLL Breeder Unit Front He in/out unit manifolds He unit inlet Cooling Plates (CPs) He unit outlet Unit backplate

18 Blanket Concept AB : He-Cooled Lithium-Lead HCLL Breeder Unit & Module: LiPb flow path PbLi inlet pol rad PbLi outlet

19 Blanket Concept AB : He-Cooled Lithium-Lead HCLL Module: Helium flow path

20 Blanket Concept AB : He-Cooled Lithium-Lead Scheme for Tritium control in blanket modules and associated circuits: List of T-sources, possible T-permeation flux and leakages) Blanket modules M LiPb Q T-Li J FW q T J M LiPb purification α Q PbLi Pump η LiPb Tritium extraction from LiPb Q PbLi Some Questions Need of T- permeation barriers? Extraction & purification efficiency? Hechemistry? Q T-He He purification η He b α Q He Blower Q He Steam generator J SG M He air purification Secondary circuit

21 Blanket Concept AB : He-Cooled Lithium-Lead Computation procedure to be used for the estimation of T- permeation in a blanket module LiPb flow and T convection via cast3m_fluid C in P T diffusion and permeation via cas3m_fluid (heat-like) Neutron code (Tripoli) Tritium production rate (at / cm3.neutron) 7,0E-03 C out Thermal-mechanical code (cast3m) 6,0E-03 5,0E-03 4,0E-03 3,0E-03 2,0E-03 1,0E-03 0,0E module radial dimension (mm)

22 Blanket Concepts B & AB : HCPB & HCLL Design Point for HCPB and HCLL blankets (selected for ITER EU-TBMs) HCLL HCPB TBR [breeder zone thickness] 1.15 [55 cm] 1.14 [46 cm] Coolant (He): T min -T max C Coolant passes Temperature: C - FW: BU: FW: Grid: BU: Coolant (He): pressure MPa 8 8 Breeder [ 6 Li enrichment] PbLi eu [90%] Li 4 SiO 4 [40%] or Li 2 TiO [~70%] 3 Multiplier - Be EUROFER: T min -T max C Breeder: T min -T max C Multiplier: T min -T max C

23 Blanket Concept C : Dual-Coolant (He & LiPb) Blanket Design Scheme and Main Features

24 Blanket Concept C : Dual-Coolant (He & LiPb) Outboard Module Horizontal Cross-section

25 Blanket Concept C : Dual-Coolant (He & LiPb) Poloidal Segmentation and Radial Built

26 Blanket Concept C : Dual-Coolant (He & LiPb) Used Neutronic 3D Model and Main Results TBR = 1.15 (90% 6 Li, inb/outb breeder zone thk: 50.5/85.5 cm) Neutron Flux Profile in Inboard mid-plane

27 Blanket Concept D : SiC/SiC - LiPb Self-Cooled Design Rational (maximization of efficiency & safety) Structural Material: SiC/SiC (low afterheat, high temperature) Blanket working principle: co-axial Pb-17Li flow to maximize outlet tempertaure Pb-17Li external circuits location: horizontal deployment, to minimize pressure Blanket remote maintenance procedure: segment geometry, maintained through vertical ports after Pb-17Li draining Potential reduction of waste quantities: separation of outboard blanket in two zones in order to minimize radioactive waste (depending on lifetime evaluations) Magnet system: possibility of high T superconductors (77 K) Plasma heating system: acknowledge of need but not evaluated Advanced conversion systems: potential for H-production

28 Blanket Concept D : SiC/SiC - LiPb Self-Cooled Assumed SiC/SiC Properties

29 Blanket Concept D : SiC/SiC - LiPb Self-Cooled Design Scheme Banana shaped Modules (poloidal Cross-Section)

30 Blanket Concept D : SiC/SiC - LiPb Self-Cooled Design Scheme Banana shaped Modules (Horizontal Cross-Section)

31 Blanket Concept D : SiC/SiC - LiPb Self-Cooled Design Scheme Banana shaped Modules (Outboard Module cross-section)

32 Blanket Concept D : SiC/SiC - LiPb Self-Cooled Banana shaped Module Replacement Procedure (through vertical ports)

33 Blanket Concept D : SiC/SiC - LiPb Self-Cooled Blanket Design Point segment : SiC f /SiC box acting as Pb-17Li container, 2 mm W protection use of 3D (industrial) SiC f /SiC 3D, extensive use of brasing Pb-17Li: T inlet/outlet 700 C/1100 C (div: 600/990 C), max. speed ~4.5 m/s dimensions outboard (front) segments: 5 modules h=8m, w=0.3m, thk=0.3m High T Shield: Pb-17Li-cooled WC, SiC f /SiC structures (energy recovered) Low T Shield: He-cooled WC with B-steel structures (as for VV) Main Analyses Results Neutronics : TBR = 1.12 (0.98 blankets, divertor, HT shield) Thermal results : T max ~1100 C (if λ =20 W/mK, thk. FW 6 mm) Acceptable stresses (see criteria details) for Hydr. pressure = 0.8 MPa Acceptable MHD pressure drops 1 independent cooling circuit for divertor, 4 for blanket, ε = 61 % (P el /P fus ) T-extraction performed on the cold leg (Pb-17Li renewal ~1100 times/day)

34 Blanket Concept D : SiC/SiC - LiPb Self-Cooled Scheme of the LiPB External Circuits Banana shaped Modules P1=2 Primary pumps 50% 12 He-detritiation system BLANKET Pb-17Li He+Tritium He 20 p 2 T Pb-17Li 10 p 2 extractor purification 10 pump Pb-17Li tank 20 Cooling Water

35 PPCS Breeding Blankets Concepts Main Blanket R&D Issues Short Term Concepts (for models A, B, AB) Further development of EUROFER (irrad.) Further development of structures manufacturing process (HIP, welds, etc ) Supporting systems, collectors and piping routes, remote mounting/dismantling Interaction LiPb/water & DWT (A) Tritium Management and Control (A, AB, B at lower extend) Permeation Coatings (A and AB) (irrad.) LiPb compatibility with EUROFER (A, AB) Ceramic and Be behavior under irradiation, T-inventory in Be (B) Pebbles beds behavior (B) Promising on-going R&D Medium Term Concept (model C) SiC/SiC related issues: FCI design (out of the main body), irrradiation, compatibility LiPb MHD: modeling of 3D inertial flow in expansion ODS: fabrication of ODS plated FW, irradiation Heat Exchanger Technology for High T LiPb T-recovery and purification (high LiPb flowrate) Integration aspects as for Short Term concepts Long Term Concept (model D) SiC/SiC related issues requiring structural functions : irradiation (thermal conductivity, burnup, lifetime), manufacturing ( joints, pipe connections), reliability, modeling, compatibility with very high v &T LiPb MHD: modeling of 3D inertial flow in expansion T-recovery and purification (high LiPb flowrate) Heat Exchanger Technology and other components for High T LiPb Integration aspects as for Short Term concepts

36 PPCS Proposed Divertor Concepts Main Functions (ref. others speakers) To control Plasma Boundary Conditions To divert magnetic lines to extract ashes and other impurities from the plasma Vertical Targets are submitted to: very high heat fluxes (up to 15 MW/m 2 ) interaction with plasma ions/neutrals Vertical Targets Designs studied only for ITER, performances TBD Additional requirements in a Power Plant: account for neutron irradiation (~10 dpa/y), use of high T-coolant for acceptable power conversion efficiency, lifetime, W-alloy appears to be the only acceptable armor material (interaction with plasma)

37 PPCS Divertor : Water-cooled concepts Low-temperature concept T inlet = 150 C Pressure : 4 MPa Main features derived from ITER divertor studies W-alloy monoblocks CuCrZr tubes OFHC compliance layer CuCrZr Temp. limited to 400 C Performances Heat flux up to 15 MW/m 2

38 PPCS Divertor : Water-cooled concepts High-temperature concept T outlet = 325 C Pressure : 15.5 MPa Main features derived from low-t concept W-alloy monoblocks EUROFER tubes Papyex compliance layer Thermal barrier in the front part Performances Heat flux up to 15 MW/m 2

PPCS Divertor : Helium-cooled concepts Target-Plate Modular concept T inlet = 600 C T outlet ~ 680 C He P : 10 MPa inboard Divertor target plates with modular thermal shield (W

39 PPCS Divertor : Helium-cooled concepts Target-Plate Modular concept T inlet = 600 C T outlet ~ 680 C He P : 10 MPa inboard Divertor target plates with modular thermal shield (W alloy) Dome and structure (ODS RAFM) Main features W-alloy tiles W-alloy & ODS-steel structures Performances Heat flux 10 MW/m 2 Divertor cartridge (RAFM) outboard pol. tor. rad.

40 PPCS Divertor : Helium-cooled concepts Principle of the target plate modular concept X X X

41 PPCS Divertor : Helium-cooled concepts Conceptual designs the vertical target and He-flow path Various design principles: HETS (ENEA) Jet impingement HEMP/HEMS (FZK) Flow promoter (pin, slot arrays)

42 PPCS Divertor : Helium-cooled concepts Component Material Min Temp. Max Temp. Materials & Temp. Windows Tiles High heat flux structure (high P He-containment) Structure and manifolds W W-alloy W-alloy ODS,... tbd (600 C) DBTT 600 C DBTT 600 C DBTT 400 C DBTT 2500 C Melting temp C 1300 C re-crystallisation 1300 C re-crystallisation C strenght limits Design Point HETS Finger width [mm] 35 He T in/out [ C] He pressure [MPa] 10 Mass flow [g/s] 30 Av. Heat Transfer Coeff. [kw/m 2 K] ~ 30 Pressure drops [MPa] HEMP/ HEMS ~

PPCS Divertor : LiPb-cooled (SiC/SiC) concept Very high-t concept T outlet = 1000 C Low pressure (MHD) Main features B r t Sect. A-A C C 31.8 B 1.1 B 2 5.5 5.5 r p Sect. C-C 12.8 2 30 1 1.

43 PPCS Divertor : LiPb-cooled (SiC/SiC) concept Very high-t concept T outlet = 1000 C Low pressure (MHD) Main features B r t Sect. A-A C C 31.8 B 1.1 B r p Sect. C-C derived from ARIES-ST studies W-alloy tiles high velocity LiPb in the toroidal direction (to limit MHD) SiC/SiC thin structures (R&D) Sect. B-B Performances A A Heat flux up to ~5 MW/m 2 p t

44 PPCS Proposed Divertor Concepts - Summary Surface heat-flux in a reactor: TBD 15 MW/m (long term)?? Water-cooled Concepts 1 - Low-Temp. (as ITER, 150 C) Known manufacturing (as ITER) Achieve heat flux of 15 MW/m 2 Lifetime of Cu-alloy under irrad. TBD Deposited Power not used for Power conversion low reactor efficiency Low R&D but low performances 2 - High-Temp. (as WCLL, 325 C) Achieve heat flux of 15 MW/m 2 Lifetime of Papyex & th. Barrier, especially under irradiation TBD Manufacturing of interface TBD Significant R&D for the steel/w joint He-cooled Concepts Achieve heat flux of 10 MW/m 2 (or more) Allow high T He-coolant (high efficiency) Avoid use of water with He-cooled blankets Development of W-alloy and ODS-steel manufacturing processes TBD Behavior of W-alloy under irradiation TBD Exp. demonstration of P-drops and heat transfer Joint W-alloys/steel TBD Significant R&D on Materials LiPb-cooled Concepts Interesting concept if used jointly to the SCLL blankets, same R&D long term issues (SiC/SiC structures), reliability, modeling, compatibility with very high v & T LiPb TBD MHD: modeling of 3D inertial flow in expansion TBD Low achieved heat flux : 5 MW/m 2, large progress expected in divertor physics TBD Very large R&D (including physics)

45 The PPCS In-Vessel Components Concepts Overall Conclusions Breeding Blankets : a major new technological challenge for Fusion towards DEMO Five blanket lines considered in the EU PPCS studies after a selection among the different possible options & materials combinations The blanket concepts corresponding to three of these lines (Water-cooled LiPb, He-cooled Ceramic/Be pebble beds, He-cooled LiPb) requires technologies which can be developed for DEMO (short term). In particular, several mock-ups of the two Hecooled concepts will be tested in ITER. The short term concepts show an acceptable efficiency (30-40%). Major design uncertainties are linked with reactor integration issues (module attachment, pipes routes, connection/disconnection, blanket coverage) Medium and long-term concepts (Dual-Coolant and LiPb Self-cooled SiC/SiC structures) show large attractiveness by higher development risk Large R&D required Divertor : a major technological improvement from ITER towards DEMO Design and R&D performed for ITER. Additional requirements for DEMO and a Power Plant have to be taken into account. Possible solutions have been evaluated with EU (PPCS). Results will be used as a basis for launching appropriate R&D.

EU PPCS Models C & D Conceptual Design

Institut für Materialforschung III EU PPCS Models C & D Conceptual Design Presented by P. Norajitra, FZK 1 PPCS Design Studies Strategy definition [D. Maisonnier] 2 models with limited extrapolations Model